RU2122525C1 - Method of removing nonferrous and heavy metals from waste waters - Google Patents

Abstract

FIELD: waste water treatment. SUBSTANCE: invention relates to waste waters from electronic and chemical industry, ferrous and nonferrous metallurgy, both for treatment of total drain and for local treatment. Waste water containing nonferrous and heavy metals is treated to adjust pH to 9-10, after which sodium orthophosphate solution is added at metal/phosphate ion weight ratio 1:(0.5-1.0) resulting in formation of insoluble metal hydroxyphosphate whose solubility is inferior to that of corresponding metal hydroxide. To isolate resulting compounds, electroflotation method with insoluble anodes is employed. Efficiency of removing nonferrous and heavy metals meets norms established for water discharge into fish- industry reservoirs. EFFECT: improved purification efficiency. 2 tbl

Description

The invention relates to methods for treating wastewater from non-ferrous and heavy metal ions, in particular nickel (Ni ²⁺ ), copper (Cu ²⁺ ), zinc (Zn ²⁺ ), chromium (Cr ³⁺ ) and can be used in enterprises electronic and chemical industries, ferrous and non-ferrous metallurgy, heavy engineering both for general drainage treatment and for local treatment.

 A known method of wastewater treatment from heavy metals by electroflotation using soluble iron and aluminum salts as coagulant (US Pat. No. 3,975,269, 1976, class. 204-149).

 The disadvantages of this method are the high consumption of coagulant and a low degree of purification.

The closest in technical essence and the achieved result is the treatment of wastewater from non-ferrous and heavy metals with the addition of Cl ^- ions and sodium hydroxide as a reagent, followed by electroflotation extraction of the resulting compounds (copyright certificate N 1675217, class C 02 F 1/465, 1991). This method is selected for the prototype.

 The disadvantages include a low degree of purification from 97.4 to 99.8%.

 The objective of the invention is to develop a method for wastewater treatment from non-ferrous and heavy metals with a high degree of purification.

The problem is solved in that in the proposed method of purification, wastewater containing non-ferrous and heavy metals is adjusted to a pH value of 9.0-10.0, then a solution of sodium orthophosphate is introduced at a mass ratio of the extracted metal to the introduced orthophosphate ion PO $\genfrac{}{}{0ex}{}{\text{3-}}{\text{4}}$ 1: (0.5-1.0) followed by electroflotation extraction of metals in the form of insoluble compounds.

 The electroflotation method is based on the adhesion of suspended particles of insoluble compounds by highly dispersed bubbles of hydrogen and oxygen gases formed during the electrolysis of water. Gas bubbles, floating in the bulk of the liquid, interact with solid particles, as a result of their mutual adhesion.

 The density of the formed aggregates from suspended particles with bubbles adhering to them is lower than the density of water, which causes their transport to the surface of the liquid and the accumulation there in the form of a foam product, which is periodically removed mechanically.

 The use of insoluble anodes made of titanium with a passivating active coating of a mixture of titanium and ruthenium oxides provides high quality cleaning and does not lead to secondary contamination of the treated effluents with the products of anode destruction.

As a result of the interaction of orthophosphate ions PO $\genfrac{}{}{0ex}{}{\text{3-}}{\text{4}}$ with the metal hydroxide Me (OH) _n in an alkaline medium, an insoluble compound of the hydroxyphosphate Me ₃ OH (PO ₄ ) _{n is formed} , the solubility of which is less than the solubility of the metal hydroxide.

In addition, PO orthophosphate ions $\genfrac{}{}{0ex}{}{\text{3-}}{\text{4}}$ and hydroxyl OH ^- , which have a negative electric charge, neutralize the positive electric charge of the metal hydroxide particles, which allows initiating the flocculation process, i.e., particle enlargement by changing the forces of interfacial interaction. An increase in particle size improves their ability to flotation process.

 The invention is illustrated by the following example.

Example. In 1 l of purified water containing 50 mg ion of nickel Ni ²⁺ , an alkali solution of NaOH is added to a pH of 9.0-10.0 and 50 mg ion of orthophosphate PO is introduced $\genfrac{}{}{0ex}{}{\text{3-}}{\text{4}}$ while the ratio of Nickel ion to the introduced orthophosphate ion is 1: 1. The solution is mixed and fed into an electroflotation apparatus to separate the resulting particles of insoluble compounds from water at a current density of 10 mA / cm ² . The electroflotation process is carried out for 7 minutes.

 Purified water is analyzed for nickel by atomic absorption spectroscopy. Similar experiments are carried out with other ratios of the metal ion to orthophosphate ion. In the same way, the solutions containing metal ions of copper, chromium, and zinc are purified. The results are presented in table. one.

 To compare the effectiveness of the known and proposed methods, wastewater was purified using the same electrode system, the design of the electroflotator and the initial concentration of metals. The results are presented in table. 2.

 In the proposed method, a high degree of purification from metals is achieved - 99.85-99.98%, which is 1-2% higher than in the known method.

 Technical and economic efficiency from the application of the proposed technical solution is due to the following factors: achieving the required degree of wastewater treatment from heavy and non-ferrous metals when discharged into fishery ponds; Reuse of purified water in the technological cycle.

Claims (1)

A method of treating wastewater from non-ferrous and heavy metals, in the presence of an ion of a soluble alkali metal salt, including electroflotation with insoluble anodes, characterized in that, in order to increase the degree of purification, orthophosphate is introduced into the purified water with a pH of 9.0-10.0 PO ions $\genfrac{}{}{0ex}{}{\text{-3}}{\text{4}}$ in the form of a soluble salt of sodium orthophosphate at a mass ratio of the recoverable metal ion to the introduced orthophosphate ion 1: (0.5-1.0).

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